/*
    vcflib C++ library for parsing and manipulating VCF files

    Copyright © 2010-2020 Erik Garrison
    Copyright © 2020      Pjotr Prins

    This software is published under the MIT License. See the LICENSE file.
*/

#include "Variant.h"
#include "split.h"
#include "cdflib.hpp"
#include "pdflib.hpp"
#include "var.hpp"

#include <string>
#include <iostream>
#include <math.h>
#include <cmath>
#include <stdlib.h>
#include <time.h>
#include <stdio.h>
#include <getopt.h>
#include "gpatInfo.hpp"
#include "makeUnique.h"

using namespace std;
using namespace vcflib;


void printHelp(void){
  cerr << endl << endl;
  cerr << "INFO: help" << endl;
  cerr << "INFO: description:" << endl;
  cerr << "     pFst is a probabilistic approach for detecting differences in allele frequencies between two populations." << endl << endl;

  cerr << R"(

pFst is a likelihood ratio test (LRT) quantifying allele frequency
differences between populations.  The LRT by default uses the binomial
distribution.  If Genotype likelihoods are provided it uses a modified
binomial that weights each allele count by its certainty.  If type is
set to 'PO' the LRT uses a beta distribution to fit the allele
frequency spectrum of the target and background.  PO requires the AD
and DP genotype fields and requires at least two pools for the target
and background.  The p-value calculated in pFst is based on the
chi-squared distribution with one degree of freedom.

)" << endl ;

  cerr << "Output : 3 columns :     "    << endl;
  cerr << "     1. seqid            "    << endl;
  cerr << "     2. position         "    << endl;
  cerr << "     3. pFst probability "    << endl  << endl;

  cerr << "INFO: usage:  pFst --target 0,1,2,3,4,5,6,7 --background 11,12,13,16,17,19,22 --file my.vcf --deltaaf 0.1 --type PL" << endl;
  cerr << endl;
  cerr << "INFO: required: t,target     -- argument: a zero based comma separated list of target individuals corresponding to VCF columns       "  << endl;
  cerr << "INFO: required: b,background -- argument: a zero based comma separated list of background individuals corresponding to VCF columns   "  << endl;
  cerr << "INFO: required: f,file       -- argument: a properly formatted VCF.                                                                  "  << endl;
  cerr << "INFO: required: y,type       -- argument: genotype likelihood format ; genotypes: GP, GL or PL; pooled: PO                           "  << endl;
  cerr << "INFO: optional: d,deltaaf    -- argument: skip sites where the difference in allele frequencies is less than deltaaf, default is zero"  << endl;
  cerr << "INFO: optional: r,region     -- argument: a tabix compliant genomic range : seqid or seqid:start-end                                 "  << endl;
  cerr << "INFO: optional: c,counts     -- switch  : use genotype counts rather than genotype likelihoods to estimate parameters, default false "  << endl;

  cerr << endl << "Type: statistics" << endl;

  printVersion() ;
}

double bound(double v){
  if(v <= 0.00001){
    return  0.00001;
  }
  if(v >= 0.99999){
    return 0.99999;
  }
  return v;
}

void loadIndices(map<int, int> & index, string set){

  vector<string>  indviduals = split(set, ",");

  vector<string>::iterator it = indviduals.begin();

  for(; it != indviduals.end(); it++){
    index[ atoi( (*it).c_str() ) ] = 1;
  }
}

double logLbinomial(double x, double n, double p){

  double ans = lgamma(n+1)-lgamma(x+1)-lgamma(n-x+1) + x * log(p) + (n-x) * log(1-p);
  return ans;

}

int main(int argc, char** argv) {

  // pooled or genotyped

  int pool = 0;

  // the filename

  string filename = "NA";

  // set region to scaffold

  string region = "NA";

  // using vcflib; thanks to Erik Garrison

  VariantCallFile variantFile;

  // zero based index for the target and background indivudals

  map<int, int> it, ib;

  // deltaaf is the difference of allele frequency we bother to look at

  string deltaaf ;
  double daf  = 0;

  //

  int counts = 0;

  // type pooled GL PL

  string type = "NA";

    const struct option longopts[] =
      {
	{"version"   , 0, 0, 'v'},
	{"help"      , 0, 0, 'h'},
	{"counts"    , 0, 0, 'c'},
        {"file"      , 1, 0, 'f'},
	{"target"    , 1, 0, 't'},
	{"background", 1, 0, 'b'},
	{"deltaaf"   , 1, 0, 'd'},
	{"region"    , 1, 0, 'r'},
	{"type"      , 1, 0, 'y'},
	{0,0,0,0}
      };

    int index;
    int iarg=0;

    while(iarg != -1)
      {
	iarg = getopt_long(argc, argv, "r:d:t:b:f:y:chv", longopts, &index);

	switch (iarg)
	  {
	  case 'h':
	    printHelp();
	    return 0;
	  case 'v':
	    printVersion();
	    return 0;
	  case 'y':
	    type = optarg;
	    cerr << "INFO: genotype likelihoods set to: " << type << endl;
	    if(type == "GT"){
	      cerr << "INFO: using counts flag as GT was specified" << endl;
	    }
	    break;
	  case 'c':
	    cerr << "INFO: using genotype counts rather than genotype likelihoods" << endl;
	    counts = 1;
	    break;
	  case 't':
	    loadIndices(ib, optarg);
	    cerr << "INFO: There are " << ib.size() << " individuals in the target" << endl;
	    cerr << "INFO: target ids: " << optarg << endl;
	    break;
	  case 'b':
	    loadIndices(it, optarg);
	    cerr << "INFO: There are " << it.size() << " individuals in the background" << endl;
	    cerr << "INFO: background ids: " << optarg << endl;
	    break;
	  case 'f':
	    cerr << "INFO: File: " << optarg  <<  endl;
	    filename = optarg;
	    break;
	  case 'd':
	    cerr << "INFO: only scoring sites where the allele frequency difference is greater than: " << optarg << endl;
	    deltaaf = optarg;
	    daf = atof(deltaaf.c_str());
	    break;
	  case 'r':
            cerr << "INFO: set seqid region to : " << optarg << endl;
	    region = optarg;
	    break;
	  default:
	    break;
	  }
      }


    if(filename == "NA"){
      cerr << "FATAL: did not specify the file\n";
      printHelp();
      exit(1);
    }

    variantFile.open(filename);

    if(region != "NA"){
      if(! variantFile.setRegion(region)){
	cerr <<"FATAL: unable to set region" << endl;
	return 1;
      }
    }

    if (!variantFile.is_open()) {
      exit(1);
    }
    map<string, int> okayGenotypeLikelihoods;
    okayGenotypeLikelihoods["PL"] = 1;
    okayGenotypeLikelihoods["GT"] = 1;
    okayGenotypeLikelihoods["PO"] = 1;
    okayGenotypeLikelihoods["GL"] = 1;
    okayGenotypeLikelihoods["GP"] = 1;

    if(type == "GT"){
      counts = 1;
    }

    if(type == "NA"){
      cerr << "FATAL: failed to specify genotype likelihood format : PL,PO,GL,GP" << endl;
      printHelp();
      return 1;
    }
    if(okayGenotypeLikelihoods.find(type) == okayGenotypeLikelihoods.end()){
      cerr << "FATAL: genotype likelihood is incorrectly formatted, only use: PL,PO,GL,GP" << endl;
      printHelp();
      return 1;
    }

    Variant var(variantFile);

    vector<string> samples = variantFile.sampleNames;
    int nsamples = samples.size();

    while (variantFile.getNextVariant(var)) {

      if(var.alt.size() > 1){
	continue;
      }


      vector < map< string, vector<string> > > target, background, total;

	int index = 0;

        for(int nsamp = 0; nsamp < nsamples; nsamp++){

          map<string, vector<string> > sample = var.samples[ samples[nsamp]];

	    if(sample["GT"].front() != "./."){
	      if(it.find(index) != it.end() ){
		target.push_back(sample);
		total.push_back(sample);
	      }
	      if(ib.find(index) != ib.end()){
		background.push_back(sample);
		total.push_back(sample);
	      }
	    }

	index += 1;
	}

	unique_ptr<zvar> populationTarget        ;
	unique_ptr<zvar> populationBackground    ;
	unique_ptr<zvar> populationTotal         ;

	using Detail::makeUnique;

	if(type == "PO"){
	  populationTarget         = makeUnique<pooled>();
          populationBackground = makeUnique<pooled>();
          populationTotal      = makeUnique<pooled>();
	}
	if(type == "PL"){
	  populationTarget     = makeUnique<pl>();
	  populationBackground = makeUnique<pl>();
	  populationTotal      = makeUnique<pl>();
	}
	if(type == "GL"){
	  populationTarget     = makeUnique<gl>();
	  populationBackground = makeUnique<gl>();
	  populationTotal      = makeUnique<gl>();
	}
	if(type == "GP"){
	  populationTarget     = makeUnique<gp>();
	  populationBackground = makeUnique<gp>();
	  populationTotal      = makeUnique<gp>();
	}
	if(type == "GT"){
          populationTarget     = makeUnique<gt>();
          populationBackground = makeUnique<gt>();
          populationTotal      = makeUnique<gt>();
        }

	populationTotal->loadPop(total          , var.position);
	populationTarget->loadPop(target        , var.position);
	populationBackground->loadPop(background, var.position);

	if(populationTarget->npop < 2 || populationBackground->npop < 2){
	  continue;
	}

	populationTotal->estimatePosterior();
	populationTarget->estimatePosterior();
	populationBackground->estimatePosterior();

	if(populationTarget->alpha == -1 || populationBackground->alpha == -1){
          continue;
        }

	if(counts == 1){

	  populationTotal->alpha  = 0.001 + populationTotal->nref;
	  populationTotal->beta   = 0.001 + populationTotal->nalt;

	  populationTarget->alpha = 0.001 + populationTarget->nref;
	  populationTarget->beta  = 0.001 + populationTarget->nalt;

	  populationBackground->alpha = 0.001 + populationBackground->nref;
	  populationBackground->beta  = 0.001 + populationBackground->nalt;


	}

	double populationTotalEstAF       = bound(populationTotal->beta      / (populationTotal->alpha      + populationTotal->beta)     );
	double populationTargetEstAF      = bound(populationTarget->beta     / (populationTarget->alpha     + populationTarget->beta)    );
	double populationBackgroundEstAF  = bound(populationBackground->beta / (populationBackground->alpha + populationBackground->beta));

	// cout << populationTotalEstAF << "\t" << populationTotal->af << endl;

	// x, n, p
	double null = logLbinomial(populationTarget->beta, (populationTarget->alpha + populationTarget->beta),  populationTotalEstAF) +
	  logLbinomial(populationBackground->beta, (populationBackground->alpha + populationBackground->beta),  populationTotalEstAF) ;
	double alt  = logLbinomial(populationTarget->beta, (populationTarget->alpha + populationTarget->beta),  populationTargetEstAF) +
	  logLbinomial(populationBackground->beta, (populationBackground->alpha + populationBackground->beta),  populationBackgroundEstAF) ;

	double l = 2 * (alt - null);

	if(l <= 0){
	  continue;
	}

	int     which = 1;
	double  p ;
	double  q ;
	double  x  = l;
	double  df = 1;
	int     status;
	double  bound ;

	cdfchi(&which, &p, &q, &x, &df, &status, &bound );

	cout << var.sequenceName << "\t"  << var.position << "\t" << 1-p << endl ;	
    }
    return 0;
}
